Supporting in situ conservation of the genetic diversity of crop wild relatives using genomic technologies

Abstract The last decade has witnessed huge technological advances in genomics, particularly in DNA sequencing. Here, we review the actual and potential application of genomics in supporting in situ conservation of crop wild relatives (CWRs). In addition to helping in prioritization of protection of CWR taxa and in situ conservation sites, genome analysis is allowing the identification of novel alleles that need to be prioritized for conservation. Genomics is enabling the identification of potential sources of important adaptive traits that can guide the establishment or enrichment of in situ genetic reserves. Genomic tools also have the potential for developing a robust framework for monitoring and reporting genome‐based indicators of genetic diversity changes associated with factors such as land use or climate change. These tools have been demonstrated to have an important role in managing the conservation of populations, supporting sustainable access and utilization of CWR diversity, enhancing accelerated domestication of new crops and forensic genomics thus preventing misappropriation of genetic resources. Despite this great potential, many policy makers and conservation managers have failed to recognize and appreciate the need to accelerate the application of genomics to support the conservation and management of biodiversity in CWRs to underpin global food security. Funding and inadequate genomic expertise among conservation practitioners also remain major hindrances to the widespread application of genomics in conservation.

potential source of novel genes and alleles for adapting crops to the ever growing problem of climate change (Hajjar & Hodgkin, 2007).
Although there has been increased interest in the conservation and use of CWRs, they still remain underutilized in crop improvement mainly due to inadequate conservation efforts (Vincent et al., 2013).
CWRs are increasingly facing natural and anthropogenic-related threats in their natural habitats leading to continuous genetic erosion and even extinctions (Bilz et al., 2011;Jarvis et al., 2008). In situ conservation has over the years emerged and been recognized globally as an important approach that complements ex situ conservation in safeguarding the world's plant genetic resources. However, compared to ex situ conservation, in situ conservation is relatively poorly developed and receives much less attention.
Conservation of plant genetic resources has over the years greatly benefited from the use of molecular based approaches.
The last decade has seen major advances in genomics particularly in DNA sequencing which have significantly increased resolution in conservation genetic studies. There has however been debate on the rationale of using genomic approaches while the traditional genetic methods can address most of the conservation related issues (McMahon et al., 2014). Previously, conservation genetics has mostly made use of only a few markers to make inferences and inform decision making on conservation practice. As will be highlighted in this study, there are many instances where the earlier molecular technologies have failed to adequately resolve critical conservation issues thereby leading to conflicts and contradictions. The line that distinguishes genetics from genomics is in some cases somewhat blurred and their distinction varies between studies (Flanagan et al., 2018;Supple & Shapiro, 2018). In this review, we consider genomic studies as those analysing whole genome data or those that use thousands of markers to probe the entire genome. We review the actual and potential application of genomics in supporting in situ CWR conservation ( Figure 1). Major progress has been made in the development of diverse genomic resources for some CWRs. Reference genome sequences are now available for a growing number CWRs  but many more remain uncharacterized. Genomics has created enormous opportunities that are enabling greater, efficient and more targeted utilization and conservation of these genetic resources. Recent large scale projects aim to coordinate the capture of genomic information for all life forms (Exposito-Alonso et al., 2020), with an emphasis on capturing genomic data before biodiversity is lost. Rare and endangered species have been a focus of such efforts.
CWRs are another group that deserve special attention.

| OVERVIE W OF THE S TATUS OF CON S ERVATI ON OF CROP WILD REL ATIVE S
Despite the importance of CWRs, a review of literature paints a picture of neglect in the conservation of these valuable genetic resources. Substantial efforts and progress have been made in the ex situ conservation of plant genetic resources, yet CWRs remain grossly under-represented in genebanks around the world. About a decade ago, it was estimated that out of the more than 7.4 accessions conserved in global genebanks (FAO, 2010), only about 2%-6% constituted CWRs (Maxted & Kell, 2009). The number of CWRs having accessions in seed banks was estimated at 6% (Maxted & Kell, 2009). However, with the recent global conservation efforts spearheaded by various institutions such as the Global Crop Diversity Trust (Dempewolf et al., 2014), aimed at improving the conservation and use of CWRs, their conservation status may have changed positively. The current in situ and ex situ CWR conservation status is likely to be known with the publication of the third state of the world report on Plant Genetic Resources for Food and Agriculture (PGRFA) whose preparation is underway.
Numerous studies have reported that even where CWRs exist in genebanks, their diversity is poorly represented, thus calling for systematic collecting efforts Khoury et al., 2019;Syfert et al., 2016). These species are better represented in in situ protected areas than in seed banks. However, even in cases where CWR populations occur in protected areas, they usually do not receive any active management and their existence and survival is just a product of the establishment of those areas (Wambugu et al., 2013).
Where in situ conservation programmes exist, they are severely limited in geographical coverage. This situation seems to be somehow changing as countries are increasingly developing targeted national in situ conservation plans for CWRs (Fielder et al., 2015;Labokas et al., 2018;Phillips, 2017;Taylor et al., 2017;Teso et al., 2018). Globally, botanic gardens play an important role in CWR conservation.
Compared to ex situ conservation where a lot more information is available about the costs involved (Koo et al., 2003;Pardey et al., 2001), little is known on the costs of establishing and maintaining in situ conservation genetic reserves. There is also paucity of information on the costs of using genomics in supporting in situ conservation. However, even with the decreasing costs of genomic technologies, the costs of using genomics, for example in demographic population monitoring, still remain higher than those of traditional genetic approaches.

| CONS ERVATION G AP ANALYS IS
A robust conservation gap analysis is important in guiding the development and implementation of an effective conservation plan.
Depending on objectives and priorities of the conservation programme, this analysis can be done at different levels namely genetic, taxon, ecogeographical and trait level using different approaches.
While conservation initiatives aim and ensure conservation of as much taxonomic, genetic and ecosystem diversity as possible, gaps have been noted. The analysis of gene level diversity and its conservation status as well as its actual conservation has been neglected (Laikre, 2010). In in situ conservation, genetic diversity has largely been overlooked as focus has mainly been on populations, species, habitats and ecosystems (Coates et al., 2018). Phylogenetic and functional diversity is rarely considered during establishment of conservation sites (Cadotte & Tucker, 2018). As will be discussed later in this paper, genomics has potential for undertaking robust monitoring of levels and patterns of genetic diversity as well as assessing conservation status at genome scale. At the trait level, genomic analysis is important in determining whether the genotypes of cultivated and wild genetic species possess target traits. This knowledge is useful in assessing whether important functional traits are adequately conserved in existing populations or germplasm collections. Genomic tools can be used to complement geographic information system (GIS) and ecology-based predictive characterization approaches such as focused identification of germplasm strategy Bhullar et al., 2009;Endresen et al., 2012) to identify populations likely to possess important adaptive traits. Identification of such traits is important in supporting trait based conservation.
Taxon and geographical level in situ conservation gap analysis can be conducted by comparing in situ diversity with that represented in herbarium samples, ex situ collection or total diversity inherent in a taxa (Maxted et al., 2008). However, the natural diversity inherent within a taxa is usually not known. Whole genome-based population genomic studies which are continually being conducted for many CWRs (Baute, 2015;Wang et al., 2014) are increasingly providing information on the molecular genetic diversity inherent in a population or taxa. In order to comprehensively capture the available genetic variation, wide sampling from the species range is recommended, including analysis of ex situ collections. Large scale sequencing efforts such as the 3,000 rice and chick pea genome projects (Varshney et al., 2021;Wang et al., 2018) are contributing to better understanding of genetic variation present in a taxa. With increased availability of information on genetic variation inherent in a taxa, genomics can potentially provide a tool to assess the threat status of a taxa or population based on levels and patterns of allelic diversity. Such assessment is likely to be relatively easy to conduct in case of localized populations or taxa as compared to those that are expansively distributed.

| PRI ORITIZ ATI ON OF C WR TA X A FOR CONS ERVATION
Due to the high number of CWRs that need protection, the budgetary requirements exceed the resources available for most conservation initiatives. Conservation managers therefore need to undertake

SupporƟng CWR geneƟc diversity access and use
Emergence of novel alleles an objective prioritization of taxa to be conserved (Maxted et al., 2006;Meilleur & Hodgkin, 2004). Prioritization is based on several criteria, key among them being relatedness between the CWR and the domesticated crop, economic value, value to breeders, endemicity, level of threat that the taxa is facing and their importance to national as well as global food security (Maxted & Kell, 2009;Phillips, 2017;Teso et al., 2018). In addition to this taxonomic based prioritization, conservation practitioners may set priorities based on functional diversity.
Several concepts which define the genetic and taxonomic relationships between the cultivated and wild species have been developed and form the principal prioritization criteria. These include the gene pool concept (Harlan & de Wet, 1971), taxon group (TG) and provisional gene pool (PGP) concepts (Maxted et al., 2006;Vincent et al., 2013). Based on the gene pool concept (Harlan & de Wet, 1971), the primary gene pool which is the closest to the crop and whose genes are most accessible for crop improvement should be given priority, followed by secondary and finally the tertiary gene pool in that order. Analysis of genome data in the Lens genus identified four gene pools which are consistent with compatibility patterns among lentil (Lens culinaris Medik) and its CWRS, thus resolving the gene pool classification in this genus which has remained inconsistent and contradictory (Wong et al., 2015). Genome sequencing is enabling assessment of the novelty of genetic resources thereby enabling their prioritization in conservation (Henry, 2013). Genomics has enabled identification of novel wild rice genetic resources in Australia and confirmed their distinctness from Asian wild rice (Waters et al., 2012) (Figure 2). Although molecular markers have greatly helped in defining genetic relationships between CWR and domesticated crops, these have in some cases remained inconclusive, contradictory or ambiguous (Baute et al., 2016;Hwang et al., 2019). Most phylogenetic studies aimed at providing insights on genetic relationships have resulted in varying levels of phylogenetic discordance. Whole genome data is providing an opportunity to resolve previously intractable phylogenetic relationships (Stein et al., 2018). Genome wide Genotyping by Sequencing data has provided a refined phylogeny of the Helianthus genus, revealing a close genetic relationship between cultivated sunflower and Helianthus winteri J. C. Stebbins, a newly described sunflower wild relative (Baute et al., 2016). Chloroplast genome analysis has also been used in reconstructing phylogenetic relationships between wild and domesticated taxa in the Oryza AA genome group (Brozynska et al., 2014;Wambugu et al., 2015) and other genera including Citrus (Carbonell-Caballero et al., 2015), Sorghum , Allium (Huo et al., 2019) and Musa . Compared to nuclear genome data, chloroplast genomes possess traits that offer particular advantages in studying phylogenetic relationships (Takahashi et al., 2008) (Small et al., 2004). The analysis of more loci in phylogenomic analysis results in increased resolution compared to traditional phylogenetic methods.
The taxon group concept is an alternative taxonomic-based system that runs hierarchically from the domesticated crop, species, series/section, subgenus, genus to tribe and was proposed by Maxted et al. (2006). It operates on the principle that there exists a great relationship between taxonomic classification and relatedness and hence crossability (Maxted et al., 2006). Taxonomic classification in many plant families has however remained inconclusive, controversial and inconsistent (Huo et al., 2019;Yang et al., 2018) thus constraining the use of this approach. Unreliable and unstable taxonomic classification has potential to negatively impact global conservation efforts (Garnett & Christidis, 2017). Genomics is providing new capabilities characterized by greater power in taxonomic studies that is enabling taxonomic revision (Coates et al., 2018). Using genotyping by sequencing data, Wong et al. (2015) proposed a taxonomic revision in the Lens genus, proposing that Lens odemensis Ladiz should be considered as a distinct species and not a subspecies under Lens culinaris. There are, however, fears that the increased power and resolution of genome scans could lead to unnecessary splitting of species (Coates et al., 2018;Isaac et al., 2004) thus complicating conservation plans. Prioritization has enabled the development of inventory lists of priority CWRs which have proved to be a valuable resource that is guiding in situ conservation efforts in various countries (Khoury et al., 2013;Vincent et al., 2013). Prioritization is also useful to conservation practitioners and geneticists as it helps in identifying a reduced number of taxa which can be logistically feasible and affordable to be subjected to detailed genomic analysis.

| S ELEC TI ON OF PRI ORIT Y CON S ERVATI ON S ITE S
In situ conservation is primarily undertaken through the establishment of in situ genetic reserves. Prior to undertaking any conservation actions, conservation managers need to undertake a systematic planning that involves both spatial and genetic prioritization of sites and CWR taxa. Different approaches have been used to identify the most suitable sites for ensuring efficient conservation of CWR F I G U R E 2 In situ populations of Australian wild rice in Lakefield National Park, North Queensland, Australia. Genome analysis has identified novel genetic diversity among these populations diversity (Moray et al., 2014;Vincent et al., 2019). Ecogeographic and genetic diversity assessment surveys of CWRs provide knowledge on genetic diversity status and patterns which is vital in guiding conservation planning and ecosystem management (Navarro et al., 2017). Next generation sequencing is providing data that is helping in prioritization of in situ conservation sites in order to ensure cost effective conservation of high amounts of biodiversity (Flanagan et al., 2018). Population genomic analysis has capacity to enable the identification of biodiversity hotspots including hot spots of rare alleles. In addition to helping in identifying appropriate locations for in situ conservation, genomics is providing insights that are informing other conservation decisions such as sampling of genetic diversity for both in situ and ex situ conservation. For example, genome analysis has reported more genetic diversity in hotter and drier areas than in cooler and wetter regions (Fitzgerald et al., 2011;Shapter et al., 2013). These genetic diversity patterns are shaped by the prevailing environmental conditions as well as the existing biotic and abiotic stresses (Tso & Allan, 2019). This suggests that ecogeographic patterns can be used as a proxy for genetic diversity in the absence of genetic diversity data (Taylor et al., 2017). When assembling genetic resources for in situ and ex situ conservation, conservation practitioners may therefore want to put relatively more sampling efforts in the drier areas compared to the wet ones. Genomic analysis of taxonomic, phylogenetic and functional diversity patterns can guide the establishment of novel protected areas.   (Curk et al., 2015). It has however been suggested that there is need to exercise caution when using GBS in identification of genotypes as it seems to have limited discriminatory capacity (Wong et al., 2015).

| S PECIE S IDENTIFI C ATI ON
The use of exome capture has been suggested to be faster and more reliable in species identification (Ogutcen et al., 2018). Genomic data complemented by geographical information has been used to identify cases of species misidentification in Helianthus petiolaris Nutt and Helianthus bolanderi A. Gray which are sunflower wild relatives (Baute et al., 2016).
DNA barcoding has emerged as a vital tool in supporting conservation. Several gene regions have previously been recommended to act as barcodes to assist in plant identification but their species discriminating capacity varies, with some performing suboptimally (CBOL Plant Working Group, 2009;Hollingsworth et al., 2016;Lahaye et al., 2008). The capacity of plastid genomes in plant identification has been demonstrated thus opening opportunities for it to potentially act as universal barcode (Nock et al., 2011). However, although the number of assembled chloroplast genomes is increasing rapidly (Daniell et al., 2016), it will require significant efforts by the scientific community to build a comprehensive chloroplast genome reference database. Once such a database is in place, chloroplast genome data is likely to become a tool that will allow authoritative species identification.
Advances in sequencing are now allowing portable, real time field based identification of closely related species using long read low coverage data obtained through nanopore sequencing technology (Parker et al., 2017). It might be debatable whether whole genome sequencing entirely for purposes of species identification is worth the efforts and cost as this might appear as data overkill. However, the data generated through this technology can be also be used for other applications such as phylogenomics (Parker et al., 2017). Other next generation sequencing based approaches such as genome skimming that can be used to generate nuclear genome-based plant bar codes have been proposed (Hollingsworth et al., 2016). Due to the current advances in molecular taxonomy, it is now possible for researchers without specialist knowledge in plant taxonomy to accurately undertake species identification. Despite advances in DNA based species identification, morphological based approaches will continue playing a critical role in identification of species that are new to science.

| MANAG ING AND MONITORING IN S ITU C WR G ENE TI C D IVER S IT Y
Active monitoring and management of in situ populations is critical

| Genomic application in monitoring indicators of genetic diversity
Loss of genetic diversity has for a long time mostly been described in abstract terms, as tools to monitor and quantify it have largely been lacking. Although there has been efforts to develop indicators of genetic erosion, not much progress has been made (FAO, 2010).
It is important that conservation managers and other practitioners adopt techniques and strategies that help in monitoring trends in genetic diversity (Leroy et al., 2018) and to-date, various such indicators have been developed or explored (Bruford et al., 2017;Fussi et al., 2016;Hoban et al., 2014;Khoury et al., 2019). With the current genomic revolution, there exists great potential for developing direct, comprehensive and robust indicators to monitor spatial and temporal patterns of genetic diversity at genome scale. However, despite its great potential, the use of molecular tools to monitor genetic diversity has largely been neglected. Proxies used to report

| Monitoring population structure
Conservation managers may need to monitor population structure in order to detect any changes as these could be caused by factors which might be of conservation concern. Population differentiation could be caused by gene flow, genetic drift or local adaptation (Shah et al., 2020). In addition to helping detect cases of population differentiation, genomics is enabling geneticists untangle the causes of the observed changes thus informing conservation management.
Genomics has significantly advanced analysis of population structure to the extent of enabling detection of cryptic lineages (Steane et al., 2015). Detection of a cryptic taxa is of conservation importance particularly when its affects the performance of other species within a threatened habitat that needs to be conserved (Barbour et al., 2009). This is especially important if the different lineages require different management practices (Bickford et al., 2007). DArT

| Identifying introgression and hybridization
Gene flow between crops and their wild relatives is of great conservation concern as it can have profound genetic impact on in situ popu- Novel variation attributed to gene flow can enhance evolutionary potential particularly in changing climates.
By providing information on temporal and spatial patterns of admixture, genome data can help monitor the spread of any desirable and undesirable alleles. This may, for example, be useful for those alleles that may have exhibited signs of leading to the emergence of potentially invasive species. As genome editing becomes popular as a genomic tool for crop improvement, there is need to consider its genetic implications during conservation as edited genes are likely to move into CWRs through gene flow (Mondon et al., 2018).
Biodiversity conservation will benefit from speciation genomics which helps analyse population divergence that leads to novel forms of biodiversity as a result of gene flow. CWRs which are isolated from potential sources of genetic contamination are particularly valuable for undertaking various genetic and genomic studies such as evolution as their genetic make-up has not been altered by gene flow (Brozynska et al., 2017). The increased capacity of genomics to detect even subtle cases of genetic admixture has revealed the magnitude of the problem thereby raising concerns on its management (Wayne & Shaffer, 2016).

| Plant reintroduction and enrichment planting
Due to various natural and anthropogenic causes, in situ populations may become threatened to the extent that their capacity to produce seed and regenerate is severely affected. Genomic analysis is providing useful information for supporting the conservation of these rare, threatened and endangered species (Figure 3). In some cases, such populations may need to be supported by introducing additional diversity to enrich the habitats. Plant reintroduction is also a common practice that is particularly useful in supporting the conservation of rare, threatened and vulnerable taxa or populations. The success of this management practice is however negatively affected by inadequate knowledge of the genetic diversity resident in the source population (Dalrymple et al., 2011;Godefroid et al., 2011). In both cases, the diversity can be sourced from ex situ conservation or naturally occurring populations. Where such materials are to be sourced from ex situ seed banks, genomics offers tools that help seed managers in selecting genetic material potentially possessing important traits that enhance their adaptive capacity (Wambugu et al., 2018). Genome

F I G U R E 3
The population of Macadamia jansenii, an endangered wild relative of domesticated macadamia, has been characterized by genome sequencing (Sharma et al., 2021) wide analysis of functional diversity of the source population will help guide reintroduction efforts as it provides insights on the capacity of the reintroduced population to adapt (Breed et al., 2019;He et al., 2016). Knowledge on phenotype-genotype relationships is increasing, with genetic markers associated with various traits being identified. Single nucleotide polymorphisms showing strong association with ecological adaptation have been reported (Parida et al., 2012) and provide a valuable resource that can potentially be used to select suitable materials. Enrichment planting material should possess high genetic diversity as this leads to greater adaptability and resilience of agroecosystems. Conservation managers can gauge the performance and fitness of the reintroduced populations by monitoring the allele frequencies of genetic variants (Shafer et al., 2015). Transcriptome sequencing will provide information on expressed genes and is therefore likely to be useful in adaptation and ecological genomics.

| IDENTIFI C ATI ON OF ADAP TIVE LO CI
Adaptive loci refers to functional variation that determines the fitness of a taxa or population in a certain environment. Unlike from contrasting environments will reveal footprints of natural selection and hence help identify genomic loci that confers adaptive capacity against climate change. However, identifying adaptive loci from genome wide data may in some cases be problematic as signatures of adaptation may be difficult to detect (Vitti et al., 2013). Using SNP diversity indices such as nucleotide diversity (π) and Tajima's D, it is possible to distinguish genomic signatures due to selection from those due to demographic processes as those due to adaptation are localized in certain regions while the others have genome wide distribution (Wakeley, 2008). There exists several methods and models for identifying loci involved in local adaptation by analysing differences in allele frequencies between populations obtained from geographical regions with contrasting environments. Some of these include BayEnv (Gautier, 2015;Günther & Coop, 2013), BayPass (Gautier, 2015) and BEDASSLE (Bradburd et al., 2013). These methods may help to identify geographical areas with unique variants or high levels of genetic diversity, both of which are important considerations when establishing in situ conservation sites.
Adaptive variation has mainly been identified at the nuclear genome but chloroplast genome analysis has recently revealed functional chloroplast genes that confer adaptive variation to diverse ecological conditions . Where information on adaptive variation is lacking for a particular taxa or population, genome scale SNP variation data may be used as a rough indicator of functional diversity and hence potential adaptability (He et al., 2016). It is predicted that due to climate changes, most species will shift their species range thus negatively impacting the suitability of current protected areas to conserve such species (Aguirre-Gutiérrez et al., 2017;Beaumont et al., 2011;Pecl et al., 2017). Incorporating genomic data into models that predict the response of species to future climates has been found to increase the accuracy of the predictions (Razgour et al., 2019). Evolutionary genomics is providing great insights on plants response to climate change (Aguirre-Liguori et al.,

2021). Genomic analysis of genetic resources collected from regions
possessing "future" climates might help identify loci necessary for imparting local adaptation in those regions. Transcriptome analysis is advancing knowledge and providing useful insights on the candidate genes and pathways likely to be associated with important adaptive traits in CWRs (Xu et al., 2014;Zeng et al., 2014). Such analysis has identified SNP markers associated with economically important traits. These trait-linked or trait-associated genetic markers are not only useful for crop improvement but also for guiding conservation actions. Once adaptive loci has been identified in CWRs, genomic tools can help introduce these adaptive alleles into domesticated crops in a targeted manner in order to increase adaptability.

| ACCE SS AND UTILIZ ATI ON OF IN S ITU G ENE TIC D IVER S IT Y
In order to ensure success and sustainability of in situ CWR conservation, utilization of the conserved genetic resources should form an important component of the overall conservation strategy.
One of the major challenges that have hindered the effective use of CWRs in research and crop improvement programmes is the inadequate understanding of their potential genetic value and unavailability of other important information. Genomics has expanded our understanding of the genetic architecture of functionally important traits. Some of these include leaf rust resistance in wheat and its wild relatives (Fatima et al., 2020;Liu et al., 2017), seed composition traits and adaptation to abiotic stresses in wild soybean (Glycine soja) Leamy et al., 2017) and local adaptation in teonsite, wild relative of maize (Pyhäjärvi et al., 2013). This includes the identification of genetic markers associated with such traits thus aiding in marker-assisted selection. Domestication of new species presents another opportunity for enhancing the utilization of in situ CWR populations. While genomics has found great application in supporting the use of in situ genetic resources, this section is not intended to give a detailed review of this subject as it is beyond the scope of this paper. There are several reviews on the use of CWRs in crop improvement with the goal of enhancing food and nutritional security .

| Accelerating domestication of new crops
Domestication marks a major deliberate effort of promoting the use of wild plants by manipulating their genetic and phenotypic traits in order to suit the needs of human kind. Genomics presents tools, resources and knowledge to accelerate domestication of new species thus potentially enhancing food and nutritional security . Genomics has enabled identification of various domestication genes and provided knowledge on functional importance of their allelic variation (Wambugu et al., 2021). These genomic advances are providing insights on genetic histories of important crops and the geographical spread of traits that may have been selected during domestication (Tripodi et al., 2021). Manipulation of domestication loci using current genomic technologies has potential of accelerating domestication of new species from CWR (Gasparini et al., 2021;Henry, 2012;Valle-Echevarria et al., 2021). Genomics is for example assisting in the domestication and improvement of intermediate wheat grass (Thinopyrum intermedium L.) which is a perennial CWR of wheat (Kantarski et al., 2017;Zhang et al., 2016).
Genome editing targeting six loci controlling agronomically important traits enabled the accelerated de novo domestication of wild tomato (Solanum pimpinellifolium L.) (Zsögön et al., 2018). In situ genetic reserves of CWRs increase availability of these taxa and presents an opportunity for human beings to interact, study and assess their food, nutritional, forage, medicinal and aesthetic value, which ultimately may lead to domestication. Deploying genomic resources such as trait-associated SNPs to select genotypes possessing traits that are favoured by communities, breeders and researchers is likely to promote utilization and therefore enhance sustainability of the conservation programmes. The enhanced capacity in genome capacity is playing a major role in supporting plant biosecurity, particularly with regard to phytosanitary management.

| Preventing misappropriation of in situ genetic diversity
Provisions that allow utilization of in situ CWR genetic diversity should be tempered with appropriate laws and regulations that prohibit illegal harvesting and over-exploitation that could threaten the survival of the CWRs. Such regulatory frameworks should have sufficient and enforceable safeguards that helps prevent bio-piracy.
Molecular analysis is aiding law enforcement and regulatory authorities in detecting cases of illegal harvesting and trade of wild populations (Aubriot et al., 2013;Hartvig et al., 2015). Bio-piracy remains a major ethical challenge that hinders effective conservation and efficient utilization of biodiversity. A key element of bio-piracy is that access to genetic resources is not followed by fair and equitable sharing of benefits. Numerous cases of bio-piracy have been reported around the world (Landon, 2007;Robinson, 2010 (Halewood et al., 2018;Sherman & Henry, 2021). There is need for an effective and transparent monitoring system that prevents digital bio piracy and ensures equitable benefits are paid to genetic resource providers (Sherman & Henry, 2021). An effective and efficient system might motivate genetic resource providers to put in place supportive mechanisms that allow unhindered access thus enhancing access, transfer and utilization of conserved germplasm. The fact that sequence data is sometimes not unique to a particular biological sample might make tracking complicated thereby making it difficult to determine who is rightfully entitled to receive the access benefits (Scholz et al., 2020). In relation to in situ conservation, it is important to put in place a system that ensures that funds obtained from access to genetic resources and associated sequence data are utilized to support conservation activities.

| Breeding for climate resilience
Climate change currently poses the single largest threat to world agriculture and global food security. Although CWR populations are facing immense threats in the wild due to climate change, those populations that will successfully withstand these threats will be a useful source of genes for breeding for increased climate resilience.
Genomics is providing tools to dissect the genetic basis of important traits and understand the functional trait diversity that is available in CWRS. Information on candidate genes and trait associated genetic markers is important in accelerating the use of CWRs in breeding programmes. The use of CWRs in crop improvement is particularly important in crops where genetic gain has been low as a result of inadequate variation in the domesticated gene pool for key target traits. Genomic data has enabled identification of regions that have lost important genetic diversity during the domestication process (Wang et al., 2009). This will facilitate targeted reintroduction of this diversity into cultivated taxa. The greatest contribution of CWRs in crop improvement is in imparting biotic and abiotic resistance (Dempewolf et al., 2017). Some of the significant contributions of CWRs in crop breeding include the introduction of resistance to late blight from wild potato Solanum demissum Lindl and stem rust from wild wheat Aegilops tauschii Coss into the respective cultivated gene pool (Prescott-Allen & Prescott-Allen, 1986). In situ conservation is important in supporting breeding using CWRs by not only increasing availability of these resources but also imparting the necessary adaptive traits through the evolutionary processes that take place in different ecogeographical areas.

| CHALLENG E S AND FUTURE PROS PEC TS
One of the major challenges facing in situ conservation is that the majority of CWRs are poorly studied and may not have a lot of genomic information and resources which may be required to guide conservation management. For species with limited genomic information, there have been considerable advances in genomic technologies allowing genome wide marker discovery, even for poorly studied taxa. Genotyping by sequencing is a powerful marker technology which is suitable for species with no reference genome sequence (Elshire et al., 2011). Inadequate knowledge on various aspects of relevance to conservation has continued to hinder conservation efforts. For example, information on available functional variation and its genetic underpinnings is critical in selecting adapted germplasm but is lacking for many CWRs. Information on genome environment associations (GEA) is not available for a vast majority of CWRs, making it difficult to match CWR populations with the right environment for in situ conservation.
The cost, computational requirements and necessary bioinformatic expertise for deploying genomics is high and may be beyond the reach of most conservation practitioners thus hindering its real world application (Flanagan et al., 2018). Although sequencing costs have reduced dramatically over the last decade, genome-wide analysis, particularly of a large number of samples, is still not affordable for resource constrained conservation initiatives. As we continue to transition from genetic studies based on few molecular markers to genome-wide analysis, selection of correct study designs, data analysis and interpretations thereof are emerging as significant challenges (Wambugu et al., 2019). Although there appears to be general agreement that genomics presents a promising tool to support conservation, there is a debate as to whether the field of conservation genomics has matured enough to find real application into conservation practice (Shafer et al., 2015). Many policy makers and conservation managers have failed to recognize and appreciate the potential of genomics in conservation and management of biodiversity (Hunter et al., 2018). Moreover, it has been acknowledged that genomics might in some cases not lead to improved conservation management practices (Allendorf et al., 2010), Funding and inadequate genomic expertise among conservation practitioners also remain major hindrances to the widespread application of genomics in conservation. Training programmes on the use of genomics in conservation should be developed for conservation managers. The field of genomics is evolving rapidly and there is no telling what the future holds in terms of its capacity and application in conservation.
In future, genome editing might offer an opportunity to support PGR conservation by introducing novel alleles that confer adaptive capacity against climate change as well as removing deleterious ones that reduce fitness (Breed et al., 2019;Johnsson et al., 2019;Supple & Shapiro, 2018). However, despite its potential, genome editing carries with its risks and dangers that should be carefully considered before deploying it in PGR conservation. This might particularly be helpful for those species that are seriously threatened by environmental stresses or general lack of adaptation capacity. Public policies on biodiversity conservation and agricultural production are often contradictory, with differing stakeholders and government agencies being responsible. Genomics is widely used in crop improvement and is increasingly used in biodiversity management.
Genomics of CWRs may have suffered from these competing perspectives in policy and funding for genomics tools, with CWRs being seen as a biodiversity problem for agriculture policy makers and an agricultural issue by biodiversity policy makers. If these interest groups are able to collaborate, it creates the opportunity for policy designed to support biodiversity and policies aiming to support agriculture and food security to be harmonized around use of genomic analysis to support conservation and utilization. An increased alignment of policy would ensure progress in the conservation of CWRs to support food security.